JP2009089546A - Permanent magnet rotary electric machine for washing machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a permanent magnet rotary electric machine for a washing machine which is applicable to high-speed rotation and has good recyclability. <P>SOLUTION: The permanent magnet rotary electric machine has a stator on which armature windings of concentrated winding are provided so as to surround teeth in a plurality of slots formed in a stator core. Permanent magnets are inserted into a plurality of recessed portions formed on the outside circumference of a yoke core. A rotor having magnetic pole cores covering the top parts of permanent magnets is supported rotatably via a prescribed gap on the inside circumference of the stator. The magnetic pole cores, the permanent magnets, and the yoke core are molded with a synthetic resin. The magnetic pole cores are not mechanically coupled to the yoke core. The inside circumferential surface of teeth, which has a circular arc surface different from that from the rotor center, and the outside circumferential surface of the magnetic pole cores have mutually a protruding shape. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a permanent magnet type rotating electrical machine employing a concentrated winding stator used in a washing machine.

  Inverter-driven permanent magnet electric motors are employed in rotating electrical machines that drive the rotating blades and drums of washing machines. Recently, laundry dryers have become mainstream, and the degree of dehydration of laundry during drying is important for energy saving. In order to increase the degree of dehydration of the laundry, it is conceivable to increase the rotation speed of the washing tub and the drum, and it is necessary to rotate the permanent magnet type rotating electric machine at a high speed. As a conventional example of this type of rotating electrical machine, as described in Japanese Patent Application Laid-Open No. 2006-352773, a rotor in which a 10-pole permanent magnet is built is known.

JP 2006-352773 A

  However, in the one described in Japanese Patent Application Laid-Open No. 2006-352773, the molded synthetic resin is subjected to centrifugal force, and it is necessary to increase the amount of the synthetic resin to cope with high-speed rotation. Therefore, in a washing machine using such a rotating electric machine, there is a problem that the recyclability is deteriorated.

  An object of the present invention is to provide a permanent magnet type rotating electrical machine for a washing machine that is capable of high-speed rotation and is highly recyclable.

(1) In order to solve the above-mentioned object, the present invention is used in a washing machine, and concentrated armature windings are provided so as to surround teeth in a plurality of slots formed in a stator core. A rotor having a fixed stator, in which a permanent magnet is housed in a plurality of recesses formed on the outer periphery of the yoke core, and the upper part of the permanent magnet covered with a magnetic core is a predetermined gap on the inner periphery of the stator. The magnetic pole core, the permanent magnet, and the yoke core are molded with a synthetic resin, and the magnetic pole core and the yoke core are not mechanically coupled to each other. The inner peripheral surface of the teeth having different arc surfaces and the outer peripheral surface of the magnetic pole core have a convex shape.

(2) In order to solve the above-described object, the present invention is used in a washing machine, and concentrated armature windings surround teeth in a plurality of slots formed in a stator core. A rotor having a permanent magnet accommodated in a plurality of recesses formed on the outer periphery of the yoke iron core and having the upper portion of the permanent magnet covered with a magnetic pole iron core is provided on the inner circumference of the stator. The magnetic pole core, the permanent magnet, and the yoke core are molded with a synthetic resin, and the magnetic pole core and the yoke core are not mechanically coupled to each other. When the distance from the inner peripheral surface is Hg, (Hg / Hd) <(R1 / R0).
(3) In order to solve the object, the present invention is used in a washing machine, and concentrated winding armature winding is applied so as to surround teeth in a plurality of slots formed in a stator core. A rotor having a permanent magnet accommodated in a plurality of recesses formed on the outer periphery of the yoke iron core, and a rotor whose upper surface is covered with a magnetic pole iron core with a predetermined gap on the inner circumference of the stator. The magnetic pole core, permanent magnet, and yoke core are molded with synthetic resin, and the magnetic pole core and yoke core are not mechanically coupled. It is characterized by being 9 mm or less.
(4) In order to solve the above-described object, the present invention is used in a washing machine, and concentrated armature windings surround teeth in a plurality of slots formed in a stator core. A rotor having a permanent magnet accommodated in a plurality of recesses formed on the outer periphery of the yoke iron core and having the upper portion of the permanent magnet covered with a magnetic pole iron core is provided on the inner circumference of the stator. A magnetic pole core, permanent magnet, and yoke core are molded with a synthetic resin, and the magnetic pole core and yoke core are not mechanically coupled to each other. The inner peripheral surface of the teeth having different arc surfaces and the outer peripheral surface of the magnetic pole core have a convex shape, the radius of the rotor is R0, and the distance to the position closest to the rotor center on the inner peripheral surface of the permanent magnet Where R1 is the ratio (R1 / R0)> 0. It is characterized by being 95.

  According to the aspect of the present invention, such a configuration causes the teeth inner circumferential surface of the stator and the outer circumferential surface of the magnetic pole core of the rotor to be convex with each other, so that the gap between the stator and the rotor changes, and the minimum Since the gap becomes one point, the magnetic attraction force applied to the mold resin is reduced, and the amount of synthetic resin for molding can be reduced, and a washing machine capable of high-speed rotation and improved recyclability can be provided.

  Embodiments of the present invention will be described below with reference to the drawings.

  Examples of the present invention are shown below.

  FIG. 1 is an embodiment showing a radial sectional view of a permanent magnet type rotating electrical machine according to the present invention.

  FIG. 2 is an enlarged view of the stator of the permanent magnet type rotating electric machine of FIG.

  FIG. 3 is an enlarged view of the rotor of the permanent magnet type rotating electric machine of FIG.

  Description will be made with reference to FIGS.

  The permanent magnet type rotating electrical machine 1 includes a stator 2 and a rotor 3. The stator 2 includes a stator core 4 and a plurality of slots 5 (42 in the figure, the number of salient poles M = 42 in the figure) and teeth 6 divided by these slots 5. It has. The armature winding 7 (consisting of a U-phase winding 7A, a V-phase winding 7B, and a W-phase winding 7C) is a concentrated winding wound around the plurality of slots 5. A lower portion of the slot 5 is a slot opening portion 8, and a lower portion of the tooth 6 is a magnetic pole core 9 of the stator 2. The inner peripheral surface of the teeth 6 is not an arc from the rotor center O, but an arc surface from the center X located on the outer diameter side on the stator 2 side, so that it protrudes toward the rotor side. Is made. When the outer diameter of the rotor 3 is R0, the maximum gap between the inner peripheral surfaces of the teeth 6 is Hg.

  In the rotor 3, rare earth permanent magnets 12 are disposed in recesses 11 disposed on the outer peripheral side of the yoke core 10 (56 in the figure, the number of rotor magnetic poles P = 56), and above the rare earth permanent magnet 12. The magnetic pole core 13 of the rotor 3 having a convex shape is arranged, and magnet locking portions 14 extending from the magnetic pole core 13 are provided on both sides of the rare earth permanent magnet 12. When the rotor 3 is rotated in this state, the rare earth permanent magnet 12 and the magnetic pole core 13 pop out. Therefore, the yoke iron core 10, the rare earth permanent magnet 12 and the magnetic pole core 13 are molded by the synthetic resin 15 and the constituent members are popped out. It is preventing. The distance to the position closest to the rotor center on the inner peripheral side of the rare earth permanent magnet 12 is the radius R0 of the R1 rotor 3, and the outer peripheral surface of the magnetic pole core 13 is not an arc from the rotor center O, but the rotor 3 Since a circular arc surface from the center Y located on the inner diameter side is formed, a stepped portion 16 having a height Hd is formed between the upper portion of the magnet locking portion 14 and the outer peripheral surface of the magnetic pole core 13.

  Here, since the outer peripheral surface of the rotor 3 and the inner peripheral surface of the tooth 6 are convex with each other, the gap length between the outer peripheral surface of the rotor 3 and the inner peripheral surface of the tooth 6 varies like a sine curve. To do. That is, the yoke iron core 10, the rare earth permanent magnet 12 and the magnetic pole iron core 13 are molded with the synthetic resin 15, but the peeling force applied to the molded synthetic resin 15 is the rotational force, centrifugal force, and rare earth permanent magnet. Magnetic attraction between 12 and teeth 6 is obtained. Since the force is related to the size of the gap, if the gap length of the sine curve is considered, the rotor 3 can be stably manufactured by molding considering the force at the minimum gap. If the force applied to the magnetic core 13 is weakened, the amount of the synthetic resin 15 used as the molding material can be reduced.

  Here, the radius of the rotor 3 is R0, and the distance to the position closest to the rotor center on the inner peripheral side of the rare earth permanent magnet 12 (the minimum radius of the recess 11 arranged on the outer peripheral side of the yoke core 10) is R1. , The ratio (R1 / R0) is made larger than 0.95. In the embodiment shown in FIGS. 1 and 3, the radius R0 of the rotor 3 is 104.0 mm, and the distance R1 to the position closest to the rotor center on the inner peripheral side of the rare earth permanent magnet 12 is 100. .2mm. As a result, the ratio (R1 / R0) of the radius R0 of the rotor 3 and the distance R1 to the position closest to the rotor center on the inner peripheral side of the rare earth permanent magnet 12 is 0.963. In addition, the thickness Hb of the magnetic pole center of the magnetic pole core 13 provided on the upper part of the permanent magnet is 1.9 mm, and the radial thickness Hm of the rare earth permanent magnet 12 is 1.9 mm.

  Although the thickness Hb of the magnetic pole center of the magnetic core 13 is 1.9 mm, the thinner the thickness Hb, the better the characteristics. However, the magnetic pole core 13 itself is a laminated electromagnetic steel sheet, and a caulking portion is required for lamination. The minimum diameter of the caulking part is about 0.6 mm, and if the iron core width necessary for both of the minimum diameters of the caulking part is 0.5 mm, the thickness Hb of the magnetic core 13 is 1.6 mm and the center Y The change in the height due to the arc portion from about 0.3 mm is about 0.3 mm, and the thickness Hb of the magnetic pole center of the magnetic core 13 is 1.9 mm. Since the thickness Hb of the magnetic pole center of the magnetic core 13 is also related to the strength of the caulking portion, 1.9 mm or 1.8 mm is a limit in manufacturing.

  Incidentally, in the example shown in Japanese Patent Laid-Open No. 2006-352773, the value corresponding to R1 / R0 is about 0.86, and it can be said that the thickness Hb of the magnetic core 13 and the radial thickness Hm of the rare earth permanent magnet 12 are thick. .

The amount of the synthetic resin to be used is roughly 1908 mm ² in the conventional example, and in the present invention, π (104 ² -100.2 ² ) / 4 = 609 mm ² . The amount of synthetic resin is related to the thickness and the cross-sectional area of the magnetic pole core / rare earth permanent magnet, but if you want to make effective use of the magnetic flux of the rare earth permanent magnet, it will be the same form and linked to the calculated value of the above cross-sectional area. .

  That is, according to the present invention, the amount of molded synthetic resin can be reduced by 68% (1- (609/1908) = 0.68), and the amount of synthetic resin affecting the environment can be reduced. And recyclability can be improved.

  In the above, the ratio of the height Hd of the paragraph 16 and the maximum gap Hg of the inner peripheral surface of the tooth 6 is 1.4 / 1.5 = 0.933, and (Hd / Hg) <(R1 / R0) Is established. When the maximum gap Hg becomes smaller, the above equation does not hold, and the height Hd of the paragraph 16 is also related.

  FIG. 4 shows a configuration example of a washing machine equipped with the permanent magnet type rotating electrical machine of the present invention. The washing machine 50 includes a water tank 53 that is suspended and supported inside a housing 51 via a suspension 52, and a laundry that is rotatably disposed inside the water tank 53 and into which laundry (not shown) is placed. It has a tank 54 and a rotary blade 55 that is disposed at the bottom of the laundry tank 54 and stirs the laundry in the laundry tank 54. The permanent magnet type rotating electrical machine 1 is fixed to a fixed plate 56 at the bottom of the water tank 53, and a hollow rotating shaft 58 is provided outside the washing machine drive shaft 57 (the output shaft of the permanent magnet type rotating electrical machine 1).

  That is, when the washing machine drive shaft 57 that is the output shaft of the permanent magnet type rotating electrical machine 1 rotates, the rotating blades 55 rotate to stir the laundry, and the washing operation is performed. Further, when the washing tub 54 is rotated at a high speed without rotating the rotary blade 55, a dehydrating operation is performed. By blowing warm air into the washing tub 54 (not shown), the drying operation is started.

  Energy saving can be achieved if the drying time is shortened. The drying time becomes shorter as the degree of dehydration of the laundry increases. In order to increase the degree of dehydration, it is necessary to rotate the rotating electrical machine at high speed. In order to rotate at high speed, the strength of the molded synthetic resin becomes a problem. Therefore, in the present invention, the thickness Hb of the magnetic pole center of the magnetic core 13 and the thickness Hm of the rare earth permanent magnet 12 are set to be not more than 4 times Hs, so that the centrifugal force applied to the synthetic resin can be reduced to rotate at high speed. A rotating electrical machine can be provided.

  According to the above configuration, when the radius of the rotor 3 is R0 and the distance to the position closest to the rotor center on the inner peripheral side of the rare earth permanent magnet 12 is R1, the ratio (R1 / R0) is 0. 95, and the thickness Hb of the magnetic pole center of the magnetic pole core 13 and the thickness Hm of the rare earth permanent magnet 12 are set to be not more than four times the thickness Hs of the magnet engaging portion of the magnetic pole iron core 13. It is possible to provide a washing machine that can reduce the amount of molded synthetic resin, enable high-speed rotation, and improve recyclability.

The radial direction sectional view of the permanent magnet type rotating electrical machine by the present invention. The enlarged view of the stator of the permanent-magnet-type rotary electric machine of FIG. The enlarged view of the rotor of the permanent magnet type rotary electric machine of FIG. The structural example of the washing machine carrying the permanent magnet type rotary electric machine of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Permanent magnet type rotary electric machine 2 Stator 3 Rotor 4 Stator iron core 5 Slot 6 Teeth 7 Armature winding 8 Slot opening 9 Stator magnetic pole core 10 Yoke iron core 11 Recessed part arranged on the outer peripheral side of the yoke iron core 10 12 Rare Earth Permanent Magnet 13 Rotor Magnetic Core 14 Magnet Locking Section 15 Synthetic Resin 16 Paragraph 50 Washing Machine 51 Housing 52 Suspension 53 Water Tank 54 Washing Tank 55 Rotor Blade 56 Fixed Plate 57 Washing Machine Drive Shaft 58 Hollow Rotating Shaft

Claims (5)

  Used in washing machines, having a stator with concentrated winding armature windings that surround teeth in a plurality of slots formed in the stator core, and formed on the outer periphery of the yoke core A rotor in which a permanent magnet is housed in a plurality of recessed portions and the upper portion of the permanent magnet is covered with a magnetic pole core is rotatably supported on the inner periphery of the stator via a predetermined gap. The permanent magnet and the yoke iron core are molded with a synthetic resin, and the magnetic pole iron core and the yoke iron core are not mechanically coupled, and the teeth having an arc surface different from the arc surface from the rotor center A permanent magnet rotating electrical machine for a washing machine, wherein an inner peripheral surface and an outer peripheral surface of the magnetic pole core have a convex shape.   Used in washing machines, having a stator with concentrated winding armature windings that surround teeth in a plurality of slots formed in the stator core, and formed on the outer periphery of the yoke core A rotor in which a permanent magnet is housed in a plurality of recessed portions and an upper portion of the permanent magnet is covered with a magnetic pole core is rotatably supported on the inner periphery of the stator via a predetermined gap. The permanent magnet and the yoke iron core are molded with a synthetic resin, and the magnetic pole iron core and the yoke iron core are not mechanically coupled, and the teeth having an arc surface different from the arc surface from the rotor center The inner peripheral surface and the outer peripheral surface of the magnetic core have a convex shape, the radius of the rotor is R0, and the distance from the inner peripheral surface of the permanent magnet to the position closest to the rotor center is R1. The height of the stepped portion of the magnetic core is Hd, and the rotor half When the distance between the farthest inner peripheral surface of the tooth from the R0 was Hg, (Hg / Hd) <(R1 / R0) and so as the permanent magnet type rotating electric machine for a washing machine, characterized in that the.   Used in washing machines, having a stator with concentrated winding armature windings that surround teeth in a plurality of slots formed in the stator core, and formed on the outer periphery of the yoke core A rotor in which a permanent magnet is housed in a plurality of recessed portions and an upper portion of the permanent magnet is covered with a magnetic pole core is rotatably supported on the inner periphery of the stator via a predetermined gap. The permanent magnet and the yoke iron core are molded with a synthetic resin, and the magnetic pole iron core and the yoke iron core are not mechanically coupled, and the teeth having an arc surface different from the arc surface from the rotor center A permanent magnet type rotating electrical machine for a washing machine, characterized in that an inner peripheral surface and an outer peripheral surface of the magnetic pole core have a convex shape, and the maximum thickness of the magnetic core is about 1.9 mm or less.   Used in washing machines, having a stator with concentrated winding armature windings that surround teeth in a plurality of slots formed in the stator core, and formed on the outer periphery of the yoke core A rotor in which a permanent magnet is housed in a plurality of recessed portions and an upper portion of the permanent magnet is covered with a magnetic pole core is rotatably supported on the inner periphery of the stator via a predetermined gap. The permanent magnet and the yoke iron core are molded with a synthetic resin, and the magnetic pole iron core and the yoke iron core are not mechanically coupled, and the teeth having an arc surface different from the arc surface from the rotor center The inner peripheral surface and the outer peripheral surface of the magnetic core have a convex shape, the maximum thickness of the magnetic core is about 1.9 mm or less, the radius of the rotor is R0, and the rotation of the inner peripheral surface of the permanent magnet When the distance to the position closest to the child center is R1, , The ratio (R1 / R0)> 0.95 and made as a permanent magnet electric motor for a washing machine, characterized in that the that the.   It has a stator with concentrated winding armature windings that surround teeth in a plurality of slots formed in the stator core, and permanent magnets are housed in a plurality of recesses formed on the outer periphery of the yoke core A rotor having the upper part of the permanent magnet covered with a magnetic pole core is rotatably supported through a predetermined gap on the inner periphery of the stator, and the magnetic pole core, the permanent magnet, and the yoke iron core are synthesized. A permanent magnet type rotating electrical machine characterized by being molded with a resin and having an inner peripheral surface of the teeth and an outer peripheral surface of the magnetic pole core having convex shapes.

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